DE1418664C - Process for the production of acetylene - Google Patents

Description

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It is known to process acetylene from hydrocarbons for the production of acetylene by therdurch Exposure to high temperatures, e.g. B. by means of mixed splitting of liquid hydrocarbons an electrical discharge, hot flame gases e.g. B. raw oils, the deterrent of the product gases or that of incomplete combustion from 1000 to 1300 ° C to 300 ° C with the help of Carry out hydrocarbons with oxygen released 5 benzene vapor.

Thermal energy. The hydrocarbons It has now been found that the

must be cooled very quickly after this action, hot gases produced in acetylene production, which, in a known way, can be deterred by quenching in a fan-like manner, if that's what that is the hot gases with a liquid is made gas in a single stage with high boiling arow, ίο matic hydrocarbon oils that are higher than about It is known to boil liquids at 150 ° C for this purpose Boiling point, e.g. B. mercury to use. ratio of hydrocarbon oil to gas at least 1: 100 It is also known to use water to quench the soot-containing hot hydrocarbon oil from To use gases. The use of mercury separates the gas that quenched acetylene is dangerous because mercury, especially mercury 15 gas with low-boiling aromatic carbon silver vapor, is very harmful to health. The hydrogen oil with a specific gravity is smaller Use of water has the disadvantage that it washes out as 0.95 and up to the boiling point of the cools gases containing acetylene mixed with water vapor of low-boiling hydrocarbon oil, and those contained in the water vapor The technical progress brought about by the invented heat energy normally lost because the 20 proper procedure is achieved is to Water vapor is no longer a work that is not difficult to separate when used as a deterrent can be. In the case of the known Abbaren, olefins are formed through use quenching of the acetylene-containing gases with water of the quenching liquid boiling above 150 ° C under pressure, high-pressure water is generated - the recooling is water vapor at 165 ° C and 4 atmospheres steam or a condensate with a temperature 35 can be obtained and that the separation of above 100 ° C, but working under pressure is due to very high boiling hydrocarbons and soot inconvenient, because for this complicated apparatus the downstream washing with the lower-boiling ones are necessary. It is also known that one for aromatic hydrocarbons with a specidie Deterring the hot gases does not make it much easier for coalfish to weigh below 0.95 Can use hydrogen oils because this will be in their 30s.

the high temperatures occurring in the process decomposes In this way it is possible to discharge the hot gas

will. It is also known that the hot gases in (temperature about 1500 ⁰ C and more) in a short time deter two stages with mineral oils, said quench at about 200 ° C. When the mineral oils are quenched in the first stage, there is no noticeable cracking, which is partially cracked and the aromatic hydrocarbon oils boiling in this way, somewhat cooled gases in a second stage, i.e. the composition of the gas is quenched by the mineral oils . This method of quenching does not change, because no gaseous one has the disadvantage that the acetylene-containing gases contain impurities, for example ethylene, in which quenching occurs as a result of the breakdown of the mineral oils. Due to the high temperature the gases are contaminated. 40 becomes part of the high-boiling aromatic

It is known to use hot acetylene and / or ethylene hydrocarbon oils in chemically modified form Quench containing gases with oils (see British vaporized and the gas contains small droplets of the Patent 844 317). However, there are no hydrocarbon oils used for quenching, Note which oils are beneficial for this purpose but these contaminants can be broken down into simpler can be used. It is also known to separate 45 ways from the gas and are not over-boiling aromatic hydrocarbon oils for equivalent to those used in the cracking of coal Deterring hot hydrocarbon gases, the gases produced by hydrogen, in the production of olefins from hydrocarbon · Sub high-boiling hydrocarbon oils arise to use. The physical we stand for hydrocarbon oils that are higher than about Conditions under which this quenching takes place - 50 150 ° C boil, and especially aromatic coals are found, are however completely different from the hydrogen oils, which boil higher than about 150 ° C, e.g. conditions that are effective for deterring polynuclear aromatic hydrocarbons, hot acetylene-containing gases are necessary. It must be the volume ratio of hydrocarbon oil

therefore surprise if the quenching is hot gas should be at least 1 in 100, i. H. 100 Vossers Acetylene-containing gases with high-boiling carbon parts of the hot gas require quenching hydrogen oils the ethylene content of these gases is not increased by 1 or more parts by volume of high boiling point. Hydrocarbon oil. Under the gas volume

Another method according to the British patent- we stand the volume in the normal state. The gas font 709 035, in turn, deals with a large amount, for example, in normal cubic thermal Pyrolysis for the production of acetylene, 60 meters, the volume of hydrocarbon oil in with the aid of a hot stream of carrier gas, the cubic meters are measured. After the deterrent Combustion of methane with air produces kung contains the hydrocarbon oil the main will and that through relaxation to a speed of that originally present in the hot gas soot brought about detriment above the speed of sound.

has been, benzene for cleavage to acetylene and 65 Man then removed in the quenched then again to quench the acetylene-containing gas formed, hydrocarbon acetylene present is introduced. In German design oil vapor, entrained hydrocarbon oil droplets Document 1 144 260 has been proposed to use one and the rest of the soot with a low-boiling aroma

table hydrocarbon oil, (specific gravity less than 0.95) by washing out and cooling of the gas up to the boiling point of the low-boiling hydrocarbon oil. This procedure has the Advantage that the carbon black without the use of mechanical aids such. B. without the use of filters, completely is removed from the gas. Also the complete separation of the high-boiling aromatic Hydrocarbon oil from the acetylene-containing gas is a major advantage of the process because any residues of this oil present in the acetylene-containing gas during the condensation of that present in the gas Water vapor in the condensate form a stable emulsion, which the separation of oil and Water very difficult. By removing the soot without the use of mechanical aids a largely ash-free soot is obtained, which after its separation from the hydrocarbon oil is a valuable by-product. With the known separation of soot from acetylene-containing gases with the aid of water and coke filters, the soot is replaced by the abrasion from the coke of the coke filters contaminated so that it has a significant ash content and for normal uses can no longer be used.

The soot can be separated from the high-boiling hydrocarbon oil in a simple manner by the soot-containing oil in the known process for splitting hydrocarbon oils with Introduces the hot coke layer into this layer with the help of a swirling and swirling layer of coke. The high boiling one aromatic hydrocarbon oil evaporates undecomposed in the hot zone, while the soot on the and swirling coke is deposited. The undecomposed high-boiling aromatic hydrocarbon oil is separated from the fission gases by condensation. . . .

By low-boiling hydrocarbon oil we understand hydrocarbons, especially aromatic ones Hydrocarbons that boil higher than about 80 ° C and a specific gravity of less than 0.95, d. H. in particular specific gravity from 0.87 to 0.94, e.g. B. have 0.90.

The gas can be washed out with the low-boiling hydrocarbon oil, for example, by introducing the approximately 180 ° C hot acetylene-containing gas into a distillation and fractionating column, allowing it to rise and adding the liquid low-boiling hydrocarbon oil to the gas approximately in the middle of the column . This evaporates when it comes into contact with the hot gas, removing the heat of evaporation from it, whereby the high-boiling hydrocarbon oil condenses and can be drawn off below. The vapor of the low-boiling hydrocarbon oil rises in the column and is partially condensed at the top of the column. In this way, a reflux of low-boiling hydrocarbon oil arises in the upper part of the column, while a reflux of high-boiling hydrocarbon oil arises in the lower part of the column. As a result of these recirculations, a complete separation of the high-boiling hydrocarbon oil and an almost complete removal of the soot from the acetylene-containing gas are achieved. If the gases withdrawn from the top of the column are later cooled below the dew point of the water vapor contained in the gases, then the vapors of the low-boiling hydrocarbon oil also precipitate and a condensate is obtained in which water and hydrocarbon are present in two layers and slightly apart can be separated.
The high-boiling hydrocarbon oils separated from the gas are expediently combined and their thermal energy is usefully used for any purpose. In this way, the considerable heat energy withdrawn from the hot gas during quenching can be used for other purposes without the acetylene production having to be carried out under pressure, as must be the case when the water is added to the water during quenching of the hot gases with water or wants to utilize the heat energy passed over in a profitable manner.

The carbon black formed during the acetylene production is used in the process according to the invention from the high-boiling hydrocarbon oil was added.

Furthermore, if, as described above, the thermal energy contained in the hot oil is recovered, Then the oil is used, which is contained in a heat exchanger, for example Has largely withdrawn heat energy, expediently again to deter further acetylene-containing Gases. So the high-boiling hydrocarbon oil is circulated. With every turn the oil absorbs the soot contained in the quenched gas and thus becomes enriched with soot on. This cycle process is expediently carried out in such a way that the soot content of a cycle is achieved Outgoing high-boiling hydrocarbon oil adjusts to a maximum of about 35 percent by weight and to For this purpose, a corresponding amount of soot-containing oil is removed from the circuit and replaced with soot-free oil or oil that contains little soot is replaced.

The soot-containing oil removed from the circuit you can, for example, burn it and thus use the soot in a simple and beneficial way, or you can can, as already described above, the soot-containing oil in a device for the splitting of hydrocarbons introduce with the help of a coke swirling up and down. You can of course use the soot-containing oil also mechanically, e.g. B. remove its soot content with the help of filters or centrifuges and return the soot-free oil to the cycle described above.

The implementation of the method according to the invention is explained again, for example, by the attached schematic representation. The oxygen O ₂ and the hydrocarbon KW are heated in separate preheaters V and mixed thoroughly in the mixer M. The homogeneous mixture is converted into acetylene-containing cracked gas in a flame reaction in the combustion chamber B and the hot cracked gas is quenched with oil at Q. The cracked gas goes on to fine cleaning and into the treatment plant, while the oil is returned to Q via a heat exchanger W, in which steam is generated. A small part of the soot-containing oil is drawn off and fed into the preheater as fuel. At the same time, this amount of oil is replaced by fresh oil F. -

example 1

370 kg of petrol per hour and 250 Nm ^{3 of} oxygen are ^{heated to 360 °} C. in each case in a second preheater. the

The mixture is converted into a gas containing acetylene in a combustion chamber. At the exit of the combustion chamber, the hot cracked gas is ^{quenched with 40 m 3 of} high-boiling aromatic oil per hour. The 18O ⁰ C hot cracking gas (800Nm ³ / h) contains about 10 percent by volume acetylene and less than 0.5 g of carbon black / Nm ^3. At the same time, 650 kg of saturated water vapor per hour at 150 ° C are obtained in a heat exchanger by exchanging heat with the oil. In a downstream distillation and fractionation column, the high-boiling hydrocarbon oil entrained in the cracking gas is ^{washed out at 1.2 m 3} of toluene per hour, the mixture of cracking gas, water vapor and toluene vapor exiting at the top of the column having a temperature of about 90 ° C.

If the reaction is carried out under otherwise identical conditions, but only 6 nvVh high-boiling aromatic oil is used for quenching, a cracked gas of 280 ° C. is obtained. It contains 9.7 percent by volume of acetylene and about 3 g of carbon black / Nm ³ . Tar and asphalt deposits form in the quenching room and the pipes and equipment through which the quenched cracked gas flows gradually clog up due to the same deposits.

Example 2

In a preheater 520 Nm ³ methane and in a second preheater 300 Nm ³ oxygen each to 600 ° C are heated. The mixture is converted into a gas containing acetylene in a combustion chamber. At the exit of the combustion chamber, the hot cracked gas is quenched with a high-boiling aromatic oil. The cracked gas at 180 ° C. contains about 8 percent by volume acetylene and about 0.3 g carbon black / Nm ³ . At the same time, 700 kg of saturated water vapor at 150 ° C. per hour are obtained by exchanging heat with the oil. In a downstream distillation and fractionation column, the high-boiling hydrocarbon oil entrained in the cracked gas is ^{washed out at 1.5 m 3} of toluene per hour, the mixture of cracked gas, water vapor and toluene vapor emerging at the top of the column having a temperature of about 90 ° C.

Claims (3)

Patent claims: ίο 1. Process for the production of acetylene from Hydrocarbons due to exposure to high temperatures, quenching of the hot gas and separating the soot from the gas, characterized in that the x5 hot gas in a single stage with high boiling point quenching aromatic hydrocarbon oils boiling above about 150 ° C, whereby the volume ratio of hydrocarbon oil to gas is at least 1 to 100, the hot one containing soot Separating hydrocarbon oil from the gas, the quenched acetylene-containing gas with low-boiling aromatic hydrocarbon oil with a specific gravity less than 0.95 and washes up to the boiling point of low boiling ' cools the hydrocarbon oil. 2. The method according to claim 1, characterized in that the separated from the gas high-boiling aromatic hydrocarbon oils combined and the warmth of the hot Recovers hydrocarbon oil. 3. The method according to claim 2, characterized in that the soot content of the im Circulated high-boiling aromatic hydrocarbon oil to a maximum of 35 percent by weight and for this purpose a corresponding amount of soot-containing oil from the circuit removed and replaced with oil that is free of soot or contains little soot. 1 sheet of drawings